DE112017006488T5 - CONTROL DEVICE AND CONTROL PROCEDURE FOR AN ONBOARD ENGINE - Google Patents

Abstract

A control device for an onboard engine includes a bleed pressure control section that controls the oil bleed pressure of an oil pump, an abnormality determination section that determines whether there is an abnormality in the control of the oil bleed pressure, a target change section that determines that there is an abnormality in the control of the oil discharge pressure, executes a change process in which the target change portion increases the target discharge pressure to a value greater than that before it is determined that there may be an abnormality in the control, an upper limit setting portion that, when the discharge pressure sensor value in a Situation in which the discharge pressure is controlled based on the target discharge pressure, which is increased by an execution of the change process, does not become greater than or equal to a Abdruckdruckschwellenwert, sets an upper limit for the engine speed and the upper G increases as the Ablaßdrucksensorwert increases.

Description

Technical area

The present invention relates to a control device and a control method adapted for an onboard engine having an oil pump capable of changing the oil discharge pressure.

State of the art

Oil discharged from an oil pump circulates within an engine. If the pressure of the oil circulating within the engine is relatively low, there is a possibility that a sufficient amount of oil will not be provided to the oil-consuming portions, which are portions of the engine requiring supply of oil. The demand for oil at the oil consuming sections tends to increase as the engine speed increases.

In this regard, z. B. the engine control device, which in JP 2012 - 87729 A is described, a fail-safe control. In particular, the pressure of oil circulating within the engine can not be increased to a pressure higher than a pressure threshold in a situation where the engine speed is greater than or equal to a speed threshold, and the controller limits the engine speed to speed threshold. Execution of such fail-safe control suppresses an increase in the demand for oil at the oil-consuming portions. As a result, even if the amount of oil that can be supplied to the oil-consuming portions is relatively small, the demand for oil at the oil-consuming portions and the amount of oil actually provided to the oil-requiring portions do not substantially differ from each other from.

Summary of the invention

Problems which the invention solves

During execution of the fail-safe control mentioned above, if the engine speed reaches an upper limit, when the engine speed is increased in an attempt to accelerate the vehicle, the vehicle can not be easily accelerated.

Means of solving the problems

In accordance with one aspect, a control device for an onboard engine is provided. The onboard engine includes an oil pump capable of changing a discharge pressure and a sensor configured to detect a pressure of oil discharged from the oil pump. The control device includes a discharge pressure control section, an abnormality determination section, a target change section, and an upper limit adjustment section. The discharge pressure control portion is configured to control the oil discharge pressure of the oil pump based on a target discharge pressure which is a target value of a discharge pressure set for the oil pump and a discharge pressure sensor value which is a pressure of oil detected by the sensor. The abnormality determination section is configured to determine whether there is an abnormality in a control of the oil discharge pressure. The target changing section is configured to, when the abnormality determination section determines that there is an abnormality in the control of the oil discharge pressure, execute a change process in which the target change section increases the target discharge pressure to a value greater than that before it is determined There may be an abnormality in the control of the oil discharge pressure. The upper limit setting section is configured such that when the discharge pressure sensor value in a situation in which the discharge pressure control section controls the oil discharge pressure based on the target discharge pressure increased by execution of the change process does not become equal to or greater than a discharge pressure threshold lower than that A target purge pressure which is increased by the execution of the change process, the upper limit setting section sets an upper limit for an engine speed, and increases the upper limit as the purge pressure sensor value increases.

With the configuration described above, when it is determined that there is an abnormality in the control of the oil discharge pressure of the oil pump, the change process is performed to give the target discharge pressure compared with the value before the determination that there is an abnormality in the control of the oil discharge pressure can, increase. Even if such an increase in the target discharge pressure does not cause the oil discharge pressure to be greater than or equal to the discharge pressure threshold, an upper limit for the engine speed is set.

When an upper limit for the engine speed is set, the configuration described above increases the upper limit for the engine speed as the purge pressure sensor value increases. That is, in the case of setting an upper limit for the engine speed, the target discharge pressure is increased first in an attempt to increase the oil supply amount. The larger the amount of oil that can be supplied to the oil-consuming portions by driving the oil pump at this time, the higher it can be the upper limit can be set. Accordingly, when the oil drain pressure is relatively high, the engine speed does not easily reach the upper limit. Therefore, even if the upper limit for the engine speed is set, acceleration of the vehicle will not be bad.

On the other hand, with the configuration described above, in the case where the upper limit for the engine speed is set, the smaller the amount of oil that can be supplied to the oil-consuming portions due to a relatively small oil discharge pressure of the oil pump , the smaller the upper limit can be set. Thus, when the oil-drain pressure is relatively low, the engine speed tends to reach the upper limit, and it is possible to suppress an increase in the demand for oil at the oil-requiring portions. This limits an increase in the deviation between the demand for oil at the oil consuming sections and the amount of oil actually provided to the oil consuming sections.

That is, with the configuration described above, the value of the upper limit is determined in accordance with the value of the oil discharge pressure when the target discharge pressure is increased by the change process. Therefore, it is possible to achieve compatibility between suppressing an increase in the demand for oil at the oil-consuming portions and preventing a poor acceleration of the vehicle.

If there is an abnormality in the control of the oil discharge pressure of the oil pump, a deviation is likely to occur between the target discharge pressure and the discharge pressure sensor value. Thus, the abnormality determination section may be configured to determine that there is an abnormality in the control of the oil discharge pressure when a time duration of a state in which a difference between the discharge pressure sensor value and the target discharge pressure is greater than or equal to a difference threshold value is greater than or equal to a time duration threshold value becomes.

The target changing portion may be configured to equate the target discharge pressure with a maximum target discharge pressure in the change process, which is a maximum value of the target discharge pressure that can be set for the oil pump. As a result, when the target purge pressure is increased by execution of the change process, the purge pressure sensor value does not become greater than or equal to the purge pressure threshold value. When an upper limit for the engine speed is set, first, the target discharge pressure is changed to the maximum target discharge pressure, and the oil pump is driven at the maximum power. This allows the oil drain pressure of the oil pump to be maximized when an upper limit for the engine speed is set. Therefore, the upper limit of the engine speed can be set in accordance with the maximum drain capacity of the oil pump at this time. This suppresses poor vehicle acceleration to the maximum while inhibiting the shortage of oil provided to the oil-consuming sections.

An oil pump may be configured to be driven in synchronism with a rotation of the crankshaft of the engine. In such a configuration, when the oil pump can be driven normally, the oil drain pressure of the oil pump increases as the engine speed increases. In this regard, in the above-described control device, the discharge pressure threshold is preferably set to a larger value when the engine speed is relatively high than when the engine speed is relatively low. With this configuration, the discharge pressure threshold is larger when the oil discharge pressure is expected to increase than when the discharge pressure is not expected to increase. As a result, since the discharge pressure threshold can be set to an appropriate value, it is possible to increase the accuracy of determining whether to set the upper limit for the engine speed.

Specifically, when the upper limit for the engine speed is set, the upper limit setting section may be configured to set the upper limit larger when the purge pressure sensor value is greater than or equal to an upper limit set threshold that is less than the purge pressure threshold than when the purge pressure sensor value is less than the upper limit set threshold. In this case, the upper limit setting threshold is set to a value lower than the discharge pressure threshold.

Even if an upper limit for the engine speed is set due to a relatively small amount of oil that can be provided to the oil-requiring portions, such an abnormality may be temporary. In such a case, a sufficient amount of oil may be provided to the oil-consuming portions in the subsequent operation of the on-board engine. In this regard, the control device described above preferably includes a storage section that stores a limit operation history indicating that the onboard engine has been operated with a set upper limit for the engine speed.

In this case, when the limit operation history is stored in the storage section to the start of the onboard engine, the change process is executed, regardless of whether the abnormality determination section determines that there may be an abnormality in the control of the oil discharge pressure. When the discharge pressure sensor value in a situation in which the oil discharge pressure is controlled based on the target discharge pressure increased by execution of the change process does not become equal to or greater than a discharge pressure threshold, it is determined that the amount of oil supplied to the oil consuming portions can be provided, in the current operating state of the onboard engine is relatively small. It is thus desirable to set an upper limit for the engine speed in accordance with the purge pressure sensor value. On the other hand, when the discharge pressure sensor value becomes greater than or equal to the discharge pressure threshold value, it is determined that a sufficient amount of oil can be provided to the oil-requiring portions during the on-state engine operation. It is thus desirable not to set an upper limit for the engine speed in this case. With this configuration, even if an upper limit has been set in the previous operation of the on-board engine due to a relatively small amount of oil that could be provided to the oil-requiring portions, an upper limit is not set in the on-going engine running operation if sufficient Amount of oil can be provided to the oil-consuming sections. This configuration prevents an upper limit from being unnecessarily set.

One embodiment of the changing process allows the oil pump to be driven in a state in which the target discharge pressure is larger than when the change process is not performed. This can eliminate an abnormality in the control of the oil discharge pressure. Therefore, when the discharge pressure sensor value in a situation in which the discharge pressure adjusting section controls the oil discharge pressure based on the target discharge pressure increased by execution of the change process becomes greater than or equal to the discharge pressure threshold value, it can be determined that the abnormality in the oil discharge pressure control has been eliminated , It is thus desirable to terminate the execution of the change process. With this configuration, when an abnormality in the oil discharge pressure control is canceled by driving the oil pump in a state in which the target discharge pressure has been increased by execution of the change process, it is possible to restore the oil discharge pressure control to the normal state.

In accordance with another aspect, a control method for an onboard engine is provided. The onboard engine includes an oil pump capable of changing a discharge pressure and a sensor configured to detect a pressure of oil discharged from the oil pump. The control method includes: controlling the oil discharge pressure of the oil pump based on a target discharge pressure that is a target value of a discharge pressure that is set for the oil pump and a discharge pressure sensor value that is a pressure of oil detected by the sensor; Determining whether there is an abnormality in a control of the oil discharge pressure; when it is determined that there is an abnormality in the control of the oil discharge pressure, executing a change process to increase the target discharge pressure to a value greater than that before it is determined that there may be an abnormality in the control of the oil discharge pressure ; and when the discharge pressure sensor value in a situation in which the oil discharge pressure is controlled based on the target discharge pressure increased by execution of the change process does not become greater than or equal to a discharge pressure threshold lower than the target discharge pressure caused by the execution of the change process increasing, setting an upper limit for an engine speed and increasing the upper limit as the Ablassdrucksensorwert increases.

list of figures

• 1 FIG. 12 is a schematic diagram showing the configuration of an on-board motor and its control device according to an embodiment. FIG.
• 2 is a cross-sectional view of an oil pump, which by the control device in 1 is controlled, and illustrates a state in which the oil drain pressure is maximized.
• 3 is a cross-sectional view of the oil pump in 1 and illustrates a state in which the oil discharge pressure is minimized.
• 4 FIG. 10 is a flowchart showing a processing routine executed by an abnormality determination section of the control device in FIG 1 is executed, illustrated.
• 5 FIG. 10 is a flowchart showing a processing routine executed by a target changing section of the control device in FIG 1 is executed, illustrated.
• 6 FIG. 10 is a flowchart showing a processing routine executed by a processing routine Upper limit setting section of the control device in FIG 1 is executed, illustrated.
• 7 Fig. 10 is a diagram showing a map for setting discharge pressure thresholds in accordance with the engine speed.
• 8A FIG. 13 is a time chart showing changes in the discharge pressure sensor value and the target discharge pressure. FIG.
• 8B Fig. 11 is a timing chart showing changes in the execution state of the change process.
• 8C FIG. 13 is a timing diagram showing changes in engine speed and times at which engine speed upper limits are set. FIG.

Embodiments of the invention

A control device for an onboard engine according to an embodiment will now be described with reference to the figures.

1 shows a circulation path of oil in an onboard engine (hereinafter, simply as a motor 200 designated), which with a control device 300 Is provided. As in 1 shown contains the engine 200 an oil pan 201 , which stores oil, and a main oil channel 202 which oil in the oil pan 201 via an oil supply device 210 provided. The motor 200 also contains devices 203 which require a supply of oil. Each of these devices 203 is an example of an oil consuming section to which oil must be provided. The oil coming from the devices 203 is drained, becomes the sump 201 recycled.

The motor 200 contains a throttle valve 221 which adjusts the amount of intake air introduced into the combustion chamber via the intake passage and an injection valve 222 which injects fuel. An air-fuel mixture, which the fuel, which from the injection valve 222 is injected and contains the intake air is burned in the combustion chamber.

The oil delivery device 210 contains an oil pump 10 which is capable of changing the discharge pressure, and an oil control valve 100 , The control device 300 controls an operation of the oil control valve 100 to the oil drain pressure of the oil pump 10 to change.

The oil pump 10 will now be related to the 1 . 2 and 3 described.

The oil pump 10 is a variable displacement pump, which is driven by a rotation of the crankshaft of the engine 200 is driven. As in 2 and 3 shown contains the oil pump 10 an input shaft 11 which rotates synchronously with the crankshaft, and a housing member CS in which a receiving space 40 is defined. The recording room 40 takes an inner rotor 50 which is integral with the input shaft 11 rotates, an outer rotor 60 , which on the radially outer side of the inner rotor 50 is arranged, and an adjustment ring 70 , which is the outer rotor 60 surrounds, up.

The housing element CS has a suction port 12 for sucking in oil and a drain port 13 for draining the internal oil to the outside of the housing element CS. As in 1 is shown, is the suction port 12 with a suction oil channel 114 connected, which to the oil pan 201 leads. As in the 2 and 3 is shown, is the drain port 13 with a drainage oil channel 13a connected to the main oil channel 202 leads.

As in the 2 and 3 shown is the inner rotor 50 outer teeth 51 on the outer circumference, and the outer rotor 60 has internal teeth 61 on the inner circumference. The inner teeth 61 the outer rotor 60 are with the outer teeth 51 of the inner rotor 50 engaged. The number of internal teeth 61 One is more than the number of external teeth 51 , The outer rotor 60 becomes rotary through the adjusting ring 70 stored.

The center of rotation of the outer rotor 60 is eccentric with respect to the center of rotation of the inner rotor 50 , The outer teeth 51 of the inner rotor 50 and the inner teeth 61 the outer rotor 60 are partially engaged with each other (on the right in 2 ). The outer circumference of the inner rotor 50 and the inner circumference of the outer rotor 60 define a working chamber 41 between them. The working chamber 41 is filled with oil.

The working chamber 41 contains a section which indicates the position at which the outer teeth 51 of the inner rotor 50 with the inner teeth 61 the outer rotor 60 are engaged, to a predetermined position in the rotational direction of the input shaft 11 is enough, what by the arrow in 2 is specified. In this section, the gap between the outer teeth increases 51 and the inner teeth 61 gradually, when the rotors 50 and 60 rotate. The section where the gap between the outer teeth 51 of the inner rotor 50 and the inner teeth 61 the outer rotor 60 gradually enlarged, is connected to the suction port 12 connected. The working chamber 41 Also contains a section in which the gap between the outer teeth 51 of the inner rotor 50 and the inner teeth 61 of the outer one rotor 60 gradually shrinks when the rotors 50 and 60 rotate. This section is with the drain port 13 connected.

If the oil pump 10 is driven causes a rotation of the input shaft 11 that the respective rotors 50 and 60 rotate while they are engaged with each other. Then the oil, which is in the oil sump 201 is stored in the working chamber 41 from the suction port 12 over the suction oil channel 114 sucked and to the drainage oil channel 13a from the drain port 13 drained.

The adjusting ring 70 has an annular main body 71 , which is the outer rotor 60 holds, and a lead 72 which is in the radial direction of the rotors 50 and 60 from the outer circumference of the main body 71 projects. The main body 71 of the adjusting ring 70 has longholes 711 and 712 which each extend in a certain direction. The long holes 711 and 712 each take leadership pins 81 and 82 which are fixed to the housing element CS. This allows the adjustment ring 70 that he is in the direction of extension of the slots 711 and 712 is moved.

A first sealing element 83 is at the distal end of the projection 72 of the adjusting ring 70 provided, and a second sealing element 84 is in the main body 71 intended. The sealing elements 83 and 84 abut the side wall of the housing element CS to the space between the side wall and the outer circumference of the adjusting ring 70 seal so that the adjusting ring 70 and the sealing elements 83 and 84 a tax oil chamber 42 in the recording room 40 define.

The tax oil chamber 42 has an opening 14 , which with a control oil channel 111 connected is. Oil can from the oil control valve 100 to the tax oil chamber 42 through the control oil channel 111 and the opening 14 to be provided. The recording room 40 takes a spring 15 on which an urging force in one direction, which is the volume of the control oil chamber 42 reduced, to the projection 72 applies. The spring 15 is on the opposite side of the ledge 72 from the tax oil chamber 42 arranged. 2 shows a state in which the internal pressure of the control oil chamber 42 is relatively low, so the urging force of the spring 15 the adjusting ring 70 holds at a position at which the volume of the control oil chamber 42 is minimized. In the present embodiment, the position of the adjusting ring 70 if the volume of the control oil chamber 42 is minimized, that is, the position of the adjusting ring 70 in 2 referred to as an initial position.

If oil is the tax oil chamber 42 is provided to the internal pressure of the control oil chamber 42 in a situation in which the adjusting ring 70 is located at the initial position, the adjusting ring 70 offset from the initial position in a direction which is the volume of the control oil chamber 42 against the urging force of the spring 15 elevated. That is, the adjustment ring 70 is offset while moving in the direction of the state which is in 2 is shown, to the state which in 3 is shown rotating (the counterclockwise direction in FIG 2 ). If oil from the tax oil chamber 42 by driving the oil control valve 100 is discharged, the internal pressure of the control oil chamber 42 decreases, so that the urging force of the spring 15 the adjusting ring 70 offset in one direction, which is the volume of the control oil chamber 42 reduced. That is, the adjustment ring 70 is offset while moving in the direction of the state which is in 3 is shown, to the state which in 2 is rotated (the clockwise direction in 3 ). In other words, the position of the adjusting ring 70 by the internal pressure of the control oil chamber 42 and the urging force of the spring 15 certainly. A change in the position of the adjusting ring 70 changes the relative position at which the teeth 51 and 61 of the inner rotor 50 and the outer rotor 60 are engaged with each other, with respect to the respective openings of the suction port 12 and the drain port 13 , Therefore, the discharge pressure, which is the pressure of the oil coming from the discharge port, becomes 13 is drained, changed by the position of the adjustment ring 70 by regulating the internal pressure of the control oil chamber 42 will be changed.

In particular, the oil drain pressure of the oil pump becomes 10 maximizes when the adjustment ring 70 at the initial position, which in 2 is shown is. When the internal pressure of the control oil chamber 42 from the state in which the oil drain pressure is maximized as in 2 is increased, the increase of the internal pressure displaces the adjusting ring 70 while adjusting ring 70 in counterclockwise direction in 2 against the urging force of the spring 15 is rotated. As a result, the area associated with the suction port 12 overlaps, in the section decreases, in which the gap between the outer teeth 51 and the inner teeth 61 gradually increases when the rotors 50 and 60 rotate, and the section in which the gap between the outer teeth 51 and the inner teeth 61 gradually decreases, partially overlaps with the suction port 12 , This reduces the oil drainage pressure. In contrast, offset when the internal pressure of the control oil chamber 42 is reduced, the reduction in the internal pressure of the adjusting ring 70 while adjusting ring 70 clockwise in 3 by the urging force of the spring 15 is rotated, so that the oil drain pressure is increased.

The oil control valve 100 will now be related to the 1 . 2 and 3 described. As in the 1 and 2 is shown is the oil control valve 100 capable of changing the connection state of numerous oil passages by adjusting the position of a coil by driving an electromagnetic actuator 100A is changed. That is, the oil control valve 100 has a control connection 101 with which the control oil channel 111 connected, a provisioning port 102 with which a supply oil channel 112 connected by a drainage oil channel 13a the oil pump 10 branches off, and a drain connection 103 with which a drainage oil channel 113 connected to drain oil. Then an instruction current value locv is applied to the actuator 100A regulated by the position of the coil of the actuator 100A between a discharge position ( 2 ) in which that to the control port 101 returned oil from the drain connection 103 is dropped, and a deployment position ( 3 ), in which the the provisioning connection 102 provided oil to the control oil channel 111 from the control terminal 101 is delivered, is changed.

The control device 300 will now be referring to 1 described. The control device 300 For example, a circuit may include: 1. one or more processors operating in accordance with a computer program (software); 2. One or more dedicated hardware circuits (Application Specific Integrated Circuits: ASIC) that perform at least part of different processes, or 3. A combination thereof. The processor includes a CPU and memories such as a RAM and a ROM. The memories store program codes or instructions that are configured to cause the CPU to execute processes. The memory or computer readable medium contains some type of medium accessible by general purpose computers and dedicated computers.

As in 1 is shown, the control device 300 electrically with a discharge pressure sensor 311 , a temperature sensor 312 , a crank angle sensor 313 and an accelerator operation amount sensor 314 connected. The discharge pressure sensor 311 detects a discharge pressure sensor value PS , which is the pressure of the oil coming from the oil pump 10 is discharged, and the temperature sensor 312 detects an oil temperature TMP , which is the temperature of the oil, that of the oil pump 10 provided. Further, the crank angle sensor detects 313 an engine speed NE , which is the rotational speed of the crankshaft. The accelerator operation amount sensor 314 detects an accelerator operation amount ACC , which is the amount of operation of the accelerator pedal by the driver of the vehicle. The control device 300 is configured, an actuation of the engine 200 based on the information provided by the sensors 311 to 314 to be controlled.

The control device 300 contains as functional sections for operating the motor 200 an abnormality determination section 301 , a target change section 302 , a discharge pressure control section 303 , an upper limit setting section 304 , a storage section 305 and an injection control section 306 , Using these functional sections, the control device provides 300 an upper limit Nelm for the engine speed NE when the purge pressure sensor value PS from a target discharge pressure PTr which is a set value of the oil discharge pressure which is for the oil pump 10 is set.

The abnormality determination section 301 determines if there is an abnormality in the control of the oil drain pressure of the oil pump 10 can give. Then, when it is determined that there is an abnormality in the control of the oil-drain pressure, the abnormality determination section gives 301 an abnormality signal indicating the possibility of an abnormality to the target changing section 302 out.

The target change section 302 directs the target discharge pressure PTr from. When receiving the abnormality signal from the abnormality determination section 301 receives leads, the target change section 302 a change process. In the change process, the target change section increases 302 the nominal discharge pressure PTr to a value greater than that before the abnormality signal is obtained, that is, before it has been determined that there may be an abnormality in the control of the oil discharge pressure. The target change section 302 gives the derived target discharge pressure PTr to the discharge pressure control section 303 out. Also, the target change portion 302 when he is the target discharge pressure PTr derives by execution of the change process, a target change signal, which is the derivative of the target discharge pressure PTr indicates the upper limit setting section 304 out.

The discharge pressure control section 303 controls the operation of the oil pump 10 by pressing the actuator 100A the oil pump 10 based on the obtained target discharge pressure PTr and the discharge pressure sensor value PS passing through the discharge pressure sensor 311 is detected controls. In particular, the discharge pressure control section conducts 303 the command current value locv by a control using the target discharge pressure PTr and the discharge pressure sensor value PS and returns the instruction stream value Locv to the actuator 100A , thereby actuating the actuator 100A controlled becomes. Accordingly, the oil discharge pressure of the oil pump becomes 10 regulated.

When receiving the target change signal from the target change section 302 receives, determines the upper limit setting section 304 if he is the upper limit Nelm for the engine speed NE should set. If he determines the upper limit Nelm to set, the upper limit setting section determines 304 the upper limit Nelm using the purge pressure sensor value PS and gives the upper limit Nelm to the injection control section 306 out. If he determines the upper limit Nelm for the engine speed NE to set, the upper limit setting section stores 304 in the storage section 305 a limit actuation history indicating that the engine 200 with the upper limit set Nelm was pressed.

The injection control section 306 controls the fuel injection amount of the injector 222 and the opening degree of the throttle valve 221 based on the obtained accelerator operation amount ACC , At this time, the injection control section 306 if the upper limit setting section 304 the upper limit Nelm for the engine speed NE has set the fuel injection amount of the injector 222 and the opening degree of the throttle valve 221 such that the engine speed NE the upper limit Nelm does not exceed.

Next, referring to 4 the processing routine executed by the abnormality determination section 301 is executed to determine whether there is an abnormality in the control of the oil drain pressure of the oil pump 10 can give described. This processing routine is executed after a start of the engine 200 is completed.

As in 4 is shown in this processing routine, the abnormality determination section determines 301 , whether the target discharge pressure PTr is maintained (step S11 ). For example, it is determined that the target discharge pressure PTr is maintained when the rate of change per unit time of the target discharge pressure PTr , which by the Solländerungsabschnitt 302 is less than a rate of change threshold. On the other hand, it is not determined that the target discharge pressure PTr is maintained if the rate of change is greater than or equal to the rate of change threshold. If it is not determined that the target discharge pressure PTr is maintained (step S11 : No), the abnormality determination section leads 301 again the determination process of step S11 out.

When it is determined that the target discharge pressure PTr is maintained (step S11 : Yes), the abnormality determination section calculates 301 the difference ΔPS (ΔPS = | PTr-PS | between the target discharge pressure PTr and the discharge pressure sensor value PS and determines if the difference Aps greater than or equal to a difference threshold ΔPSTh is (step S12 ). In the case where the oil drain pressure of the oil pump 10 can be controlled in a normal way, it is unlikely that the difference Aps increased in a situation in which the target discharge pressure PTr is maintained. Accordingly, in the present embodiment, the difference threshold value becomes ΔPSTh as a reference for determining whether the oil drain pressure can be normally controlled. Therefore, if the difference Aps less than the difference threshold ΔPSTh is, determines that the control of the oil drain pressure is normal. In contrast, if the difference Aps greater than or equal to the difference threshold ΔPSTh is not determined that the oil drain pressure control is normal.

Cases in which the oil discharge pressure can not be controlled normally include a case where the oil control valve 100 can not be driven in a normal manner, a case in which the adjusting ring 70 not properly in the oil pump 10 and a case in which there is an abnormality in the temperature sensor 312 gives. That is, if there is an abnormality in the oil control valve 100 can, the oil control valve 100 not properly the internal pressure of the control oil chamber 42 the oil pump 10 control. In this case it is because the position of the adjusting ring 70 can not be properly controlled, the difference difficult Aps between the nominal discharge pressure PTr and the discharge pressure sensor value PS to reduce.

Also, if the adjustment ring 70 not properly in the oil pump 10 can be moved, even a proper adjustment of the internal pressure of the control oil chamber 42 the adjusting ring 70 not easy to move. The oil drain pressure can not be easily changed. Therefore, the difference is difficult Aps between the nominal discharge pressure PTr and the discharge pressure sensor value PS to reduce.

The target discharge pressure PTr will be in accordance with the oil temperature TPM adjusted by the temperature sensor 312 is detected. Setting the target discharge pressure PTr will be discussed below. Therefore, if there is an abnormality in the temperature sensor 312 gives, the detected oil temperature TMP from the actual oil temperature, so that the target discharge pressure PTr can not be set to an appropriate value in some cases. When the target discharge pressure PTr can not be set to a suitable value as described above, the Ablassdrucksensorwert PS even by driving the oil pump 10 by an actuation of the oil control valve 100 not closer to the target discharge pressure PTr to be brought. The difference Aps can therefore not be reduced in some cases.

Referring back to the description of the flowchart of FIG 4 the abnormality determination section repeats 301 if the difference Aps less than the difference threshold ΔPSTh (No) in step S12 is, the determination process of step S12 , On the other hand, the abnormality determination section detects 301 if the difference Aps greater than or equal to the difference threshold ΔPSTh is (step S12 : Yes), a period of time tm a state in which the difference Aps greater than or equal to the difference threshold ΔPSTh is and determines if the time period tm greater than or equal to a time duration threshold TMTH is (step S13 ). If there is an abnormality in the control of the oil drain pressure of the oil pump 10 can give a state in which the difference Aps greater than or equal to the difference threshold ΔPSTh is continued for a certain period of time. On the other hand, if there is no abnormality of the control of the oil discharge pressure, that is, if the control is normally performed, the difference Aps temporarily greater than or equal to the difference threshold ΔPSTh become. However, this state is not continued. Accordingly, in the present embodiment, the time duration threshold value becomes TMTH as a reference for determining if the time duration tm the state in which the difference Aps greater than or equal to the difference threshold ΔPSTh is, relatively long, defined. Therefore, when the time period tm greater than or equal to the time duration threshold TMTH It is determined that there may be an abnormality in the control of the oil discharge pressure. In contrast, when the period of time tm less than the time duration threshold TMTH is not to be determined that there may be an abnormality in the control of the oil discharge pressure.

If the time period tm shorter than the time duration threshold TMTH is (step S13 : No), the abnormality determination section moves 301 the processing on the step described above S12 , If the time duration Tm is greater than or equal to the time duration threshold TMTH is (step S13 : Yes), gives the abnormality determination section 301 an abnormality signal to the target change portion 302 out (step S14 ) and then terminates the processing routine.

Next, referring to 5 the processing routine executed by the target change section 302 is executed to the target discharge pressure PTr derive. The processing routine is executed in a predetermined control circuit.

As in 5 2, in this processing routine, the target changing section determines 302 Whether the above-mentioned limit operation history in the storage section 305 is stored (step S21 ). If the limit operation history in the storage section 305 is stored (step S21 : Yes), the target change section moves 302 the processing to step S23 , which will be described below. On the other hand, if the limitation operation history does not determine in the storage section 305 is stored (step S21 : No), the target change section 302 whether an abnormality signal from the abnormality determination section 301 was delivered (step S22 ). If no abnormality signal from the abnormality determination section 301 was delivered (step S22 : No), the target change section moves 302 the processing to step S26 , which will be described below. In contrast, the target change section moves 302 if an abnormality signal from the abnormality determination section 301 was delivered (step S22 : Yes) the processing to the subsequent step S23 ,

In step S23 determines the target change section 302 whether a command to stop execution of the process of changing the target discharge pressure PTr from the upper limit setting section 304 was delivered. As will be described in detail below, the command to stop the execution is a command which is executed by the upper limit setting section 304 to the target change section 302 is supplied when the upper limit setting section 304 determines that the upper limit Nelm for the engine speed NE does not have to be adjusted.

If a command for stopping execution from the upper limit setting section 304 was delivered (step S23 : Yes), the target change section moves 302 the processing to step S26 , which will be described below. On the other hand, if no instruction for stopping the execution of the upper limit setting section 304 was delivered (step S23 : No), the target change section 302 a change process for the target discharge pressure PTr out. The maximum value of the oil drain pressure of the oil pump 10 varies depending on the engine speed NE and the oil temperature TMP at this time. Therefore, in this change process, the target change portion guides 302 the maximum value of the discharge pressure, which for the oil pump 10 can be adjusted, from the ratio between the current engine speed NE and the oil temperature TMP , and puts a pressure PTr equal to the derived maximum value of the discharge pressure. In particular, in this change process, the target discharge pressure PTr to the discharge pressure, which is obtained when the oil pump 10 in the state is which in 2 shown is set. The maximum value of the discharge pressure, which can be adjusted increases as the engine speed increases NE increased and when the oil temperature TMP reduced.

If a derivative of the target discharge pressure PTr is completed by the change process, is the target change section 302 the above-described target change signal to the upper limit setting section 304 out (step S25 ) and moves the process to step S27 , which will be discussed below.

In step S26 performs the target change section 302 a normal derivation process of the target discharge pressure PTr. In the normal derivation process, the target change section detects 302 the required discharge pressures of the respective devices 203 in the engine 200 and sets the target discharge pressure PTr to the maximum required discharge pressure of the required discharge pressures. The required discharge pressures of the corresponding devices 203 tend to increase when the engine speed NE increased and when the oil temperature TMP reduced. Therefore, the target discharge pressure tends PTr , which is derived by the normal derivation process, to increase as the engine speed NE increased and when the oil temperature TMP reduced. In the present embodiment, the target discharge pressure becomes PTr which is derived by the normal derivative process, also as a reference target pressure PTRB designated. If a derivative of the target discharge pressure PTr is completed by the normal derivation process, the target change section moves 302 the process to the next step S27 ,

In step S27 gives the target change section 302 the nominal discharge pressure PTr which in step S24 or step S26 is derived to the discharge pressure control section 303 out. Thereafter, the target discharge pressure ends PTr temporarily the processing routine.

In the present embodiment, unless it is determined that there is an abnormality in the control of the oil discharge pressure of the oil pump 10 can give, the target change section 302 the normal discharge process to the target discharge pressure PTr with the reference relief pressure PTRB equate. In this situation, if it is determined that there is an abnormality in the control of the oil discharge pressure, the target change portion 302 the change process to the target discharge pressure PTr drive. That is, the target discharge pressure PTr becomes higher than the target discharge pressure PTr before it is determined that there may be an abnormality, ie, the reference target discharge pressure PTRB ,

Next, referring to the 6 and 7 the processing routine described by the upper limit setting section 304 is performed. This processing routine is executed when a predetermined delay time TD has elapsed since a target change signal from the target change section 302 was delivered.

In this processing routine, the upper limit setting section passes 304 a first discharge pressure threshold PSTh1 , a second discharge pressure threshold pSTH2 and a third discharge pressure threshold PSTh3 off (step S31 ), as in 6 is shown. Below these discharge pressure thresholds PSTh1 to PSTh3 is the third discharge pressure threshold PSTh3 the highest, second exhaust pressure threshold pSTH2 is the second highest and the first discharge pressure threshold PSTh1 is the least. The third discharge pressure threshold PSTh3 is a discharge pressure threshold for determining if the upper limit Nelm for the engine speed NE using the purge pressure sensor value PS should be set. In the present embodiment, the upper limit Nelm for the engine speed NE set when the Ablassdrucksensorwert PS less than the third discharge pressure threshold PSTh3 is. In addition, the first discharge pressure threshold is PSTh1 and the second discharge pressure threshold pSTH2 Upper limit setting thresholds for determining the value of the upper limit NELm.

In the present embodiment, the discharge pressure thresholds become PSTh1 to PSTh3 using the map which is in 7 shown is set. The oil pump 10 is a pump which is driven synchronously with a rotation of the crankshaft. Therefore, the discharge pressure sensor value is expected to be PS gets bigger when the engine speed NE is high, as if the engine speed NE is relatively low. Therefore, each of the discharge pressure thresholds increases PSTh1 to PSTh3 when the engine speed NE elevated. When the target discharge pressure PTr derived by execution of the change process, are the discharge pressure thresholds PSTh1 to PSTh3 less than the target discharge pressure PTr ,

Reverting to 6 determines the upper limit setting section 304 if the derivative of the discharge pressure thresholds PSTh1 to PSTh3 is completed, whether the Ablassdrucksensorwert PS less than the first discharge pressure threshold PSTh1 is (step S32 ). When the discharge pressure sensor value PS less than the first discharge pressure threshold PSTh1 is, is the Ablaßdrucksensorwert PS of course less than the third discharge pressure threshold PSTh3 , and the upper limit Nelm must be for the engine speed NE be set. Therefore, the upper limit setting section sets 304 if the Discharge pressure sensor value PS is less than the first discharge pressure threshold PSTh1 (Step S32 : Yes), the upper limit NELm with the first upper limit NE1 is equal to NELm (NELm = NE1) to the injection control section 306 out (step S33 ). Thereafter, the upper limit setting section moves the process to step S92 , which will be discussed below.

If the discharge pressure sensor value PS greater than or equal to the first discharge pressure threshold PSTh1 (No) in step S32 is, determines the upper limit setting section 304 whether the discharge pressure sensor value PS less than the second discharge pressure threshold pSTH2 is (step S34 ). When the discharge pressure sensor value PS less than the second discharge pressure threshold pSTH2 is, is the Ablaßdrucksensorwert PS of course less than the third discharge pressure threshold PSTh3 , and the upper limit Nelm must be for the engine speed NE be set. Therefore, the upper limit setting section sets 304 when the discharge pressure sensor value PS less than the second discharge pressure threshold pSTH2 is (step S32 : Yes), the upper limit Nelm with the second upper limit NE2 equal to which is greater than the first upper limit NE1 is, and returns NELm (NELm = NE2 ) to the injection control section 306 out (step S35 ). Thereafter, the upper limit setting section moves 304 the process to step S92 , which will be discussed below.

If the purge pressure sensor value is greater than or equal to the second purge pressure threshold pSTH2 (No) in step S34 is, determines the upper limit setting section 304 whether the discharge pressure sensor value PS less than the third discharge pressure threshold PSTh3 is (step S36 ). When the discharge pressure sensor value PS less than the third discharge pressure threshold PSTh3 is, it is necessary, the upper limit Nelm for the engine speed NE adjust. When the discharge pressure sensor value PS greater than or equal to the third discharge pressure threshold PSTh3 is, it is not necessary, the upper limit Nelm for the engine speed NE adjust. Therefore, the upper limit setting section sets 304 when the discharge pressure sensor value PS is less than the third discharge pressure threshold value PSTh3 is (step S36 : Yes), the upper limit NELm with the third upper limit NE3 equal to which is greater than the second upper limit NE2 is, and gives Nelm (NELm = NE3 ) to the injection control section 306 out (step S37 ). Thereafter, the upper limit setting section moves 304 the process to step S92 , which will be discussed below.

In step S38 stores the upper limit setting section 304 the limit operation history in the storage section 305 , Thereafter, the upper limit setting section ends 304 this processing routine.

If the discharge pressure sensor value PS greater than or equal to the third discharge pressure threshold PSTh3 (No) in step 36 is the upper limit setting section 304 a command to stop the execution of the process of changing the target discharge pressure PTr to the target change section 302 off and sets the upper limit Nelm not one (step S39 ). Thereafter, the upper limit setting section ends 304 this processing routine.

Next, referring to the 8A . 8B and 8C the operation after a start of the engine 200 described along with the benefits.

As indicated by the solid line in 8A is specified, the target discharge pressure begins PTr that he will be maintained at a first date t11 after the engine 200 is started. In the example, which in the 8A to 8C is shown, deviates the target discharge pressure PTr from the discharge pressure sensor value PS off and the difference Aps between the nominal discharge pressure PTr and the discharge pressure sensor value PS is still greater than the difference threshold ΔPSTh , as in 8A is shown. At a second time t12 the time Tm of this state reaches the time duration threshold TMTH , In this case, since it can be determined that there is an abnormality in the control of the oil discharge pressure of the oil pump 10 can give, the target discharge pressure PTr through the change process, as in 8B is shown derived. As in 8A is shown, the target discharge pressure PTr is set larger than before it is determined that there may be an abnormality in the control of the oil discharge pressure, in an attempt to increase the amount of oil that the engine the respective devices 203 can provide.

In a case where the oil control valve 100 , the oil pump 10 and the temperature sensor 312 are normal, if the target discharge pressure PTr greater than the reference target pressure PTRB is set by the change process, the target discharge pressure PTr greater than the third discharge pressure threshold PSTh3 , When the delay time TD from the second time t12 has passed (a third time t13 in 8th ), it is expected that the discharge pressure sensor value PS due to an increase in the target discharge pressure PTr has been increased sufficiently, so that the processing routine, which in 6 is shown executed.

At this time, if the adjusting ring 70 the oil pump 10 to the position which in 2 is shown, the Ablassdrucksensorwert PS to the target discharge pressure PTr elevated. That is, the discharge pressure sensor value PS is greater than the third discharge pressure threshold PSTh3 , In this case, since it can not be determined that there is an abnormality in the control of the oil drain pressure of the oil pump 10 gives, the derivative of the target discharge pressure PTr not executed by the change process. That is, the target discharge pressure PTr is derived by a normal drainage process, and the operation of the oil pump 10 is based on this target discharge pressure PTr controlled.

However, if the adjustment ring 70 even by increasing the target discharge pressure PTr through the change process not to the position which in 2 is shown, the Ablassdrucksensorwert PS less than the third discharge pressure threshold PSTh3 at a third time t13 , as in 8A is shown. In this case, since it can be determined that there is an abnormality in the control of the oil discharge pressure of the oil pump 10 there, the upper limit Nelm for the engine speed NE set as indicated by the dashed line in 8C is specified.

At the third time t13 is, although the Abdruckdrucksensorwert PS less than the third discharge pressure threshold PSTh3 is how in 8A is shown, the Ablassdrucksensorwert PS greater than the first discharge pressure threshold PSTh1 and the second discharge pressure threshold pSTH2 , Therefore, as in 8C shown is the upper limit Nelm with a third upper limit NE3 equated to whichever is greater than the first upper limit NE1 and the second upper limit NE2 is.

As described above, the larger the amount of oil which the devices can 203 by driving the oil pump 10 can be deployed at this time, the larger the upper limit Nelm be set. Therefore, in a case where the oil discharge pressure of the oil pump is 10 is relatively high, even if the engine speed NE from a fourth time t14 increased, unlikely, the engine speed NE the upper limit Nelm reached. Therefore, even if the upper limit Nelm for the engine speed NE is set, acceleration of the vehicle will not be bad. In contrast, the smaller the amount of oil which the devices 203 can be provided due to a low oil drain pressure, the lower the upper limit Nelm be set. For example, if the discharge pressure sensor value becomes PS less than the first discharge pressure threshold PSTh1 at the time, if the processing routine which is in 6 is shown executing the upper limit Nelm with the upper limit NE1 equated to the lowest among the three upper limits NE1 . NE2 and NE3 is. Thus, the engine speed tends NE for this, when the oil drain pressure is relatively low, the upper limit Nelm and it is possible to increase the oil demand on the devices 203 to suppress. This limits an increase in the deviation between the craving for oil on the devices 203 and the amount of oil, which is actually the devices 203 provided.

That is, with the present embodiment, the value of the upper limit Nelm in accordance with the value of the discharge pressure sensor value PS determined when the target discharge pressure PTr increased by the change process. Therefore, it is possible to have a compatibility between suppressing an increase in the demand for oil at the oil-consuming portions including the devices 203 and to achieve prevention of poor acceleration of the vehicle.

In the present embodiment, when the target discharge pressure PTr derived by the change process, the target discharge pressure PTr to the maximum value of the oil drain pressure of the oil pump 10 increased at this time. That is, when it is determined that there may be an abnormality in the control of the oil-drain pressure, the oil-drain pressure can be maximized. Therefore, the upper limit Nelm for the engine speed NE in accordance with the maximum drain capacity of the oil pump 10 be discontinued at this time. This suppresses, to the maximum extent, poor vehicle acceleration while inhibiting the shortage of oil provided to the oil-consuming sections.

If the oil pump 10 can be driven in a normal manner, the oil drain pressure of the oil pump increases 10 when the engine speed NE elevated. Thus, the third discharge pressure threshold value becomes PSTh3 increases when the engine speed NE elevated. The third discharge pressure threshold PSTh3 can be set larger when the oil drain pressure is expected to be relatively high than when the drain pressure is not expected to be relatively high. As a result, it is possible because the third discharge pressure threshold PSTh3 can be set to an appropriate value, the accuracy of determining whether the upper limit Nelm for the engine speed NE should be set to increase.

Also, in the present embodiment, in addition to the third discharge pressure threshold value PSTh3 the first discharge pressure threshold PSTh1 and the second discharge pressure threshold pSTH2 also increases when the engine speed NE elevated. Thus, the upper limit Nelm be set larger, if it is expected that an increase in engine speed NE makes the oil drain pressure relatively high, as if not expected to increase in engine speed NE significantly increased oil drain pressure. Therefore, will prevents an increase in engine speed NE is limited despite the fact that the discharge pressure of the oil can be increased.

If the upper limit Nelm for the engine speed NE during operation of the engine 200 is set, the limit operation history, which is the operation history, becomes the upper limit setting Nelm indicates in the memory section 305 saved. In this case, since the limit operation history in the storage section 305 while running this engine 200 is stored, the control of the oil drain pressure of the oil pump 10 using the target discharge pressure PTr (PTr> PTrB), which is derived by execution of the change process before the time period tm greater than or equal to the time duration threshold TmTh. This speeds up the determination of whether the upper limit Nelm for the engine speed NE should be set. When the discharge pressure sensor value PS less than the third discharge pressure threshold PSTh3 is, can the upper limit Nelm be equated with a value of the engine speed NE (any of NE1 . NE2 or NE3 ) corresponds. That allows the engine 200 , with the upper limit set Nelm to work early.

On the other hand, when the discharge pressure sensor value becomes PS greater than or equal to the third discharge pressure threshold PSTh3 is, the oil drain pressure of the oil pump 10 normally during operation of the running engine 200 controlled. It can thus be determined that a sufficient amount of oil is available to the devices 203 can be provided so that the upper limit Nelm not for the engine speed NE is set. That is, even if the upper limit Nelm due to a relatively small amount of oil affecting the devices 203 during the previous operation of the engine 200 was set, is the upper limit Nelm in the ongoing operation of the engine 200 not adjusted, if a sufficient amount of oil to the devices 203 can be provided. This configuration prevents an upper limit Nelm is adjusted in an unnecessary way.

If the oil pump 10 is driven in a state in which the target discharge pressure PTr is increased by an execution of the change process, an abnormality in the control of the oil discharge pressure can be eliminated. Accordingly, in the present embodiment, when the discharge pressure sensor value PS in a situation where the oil discharge pressure is based on the target discharge pressure PTr , which is increased by execution of the change process, is controlled to be greater than or equal to the third discharge pressure threshold value PSTh3 is determined that the abnormality in the control of the oil drain pressure has been eliminated. For this reason, the oil discharge pressure becomes based on the target discharge pressure PTr which is derived by the normal derivation process. That prevents the devices 203 overly oil is provided. Therefore, a deterioration of the fuel efficiency of the engine 200 limited.

The embodiment described above may be modified as follows. The upper limit Nelm is for the engine speed NE set when the Ablassdrucksensorwert PS not greater than or equal to the third discharge pressure threshold PSTh3 even if the target discharge pressure PTr increased by the change process. In this case, the limitation operation history does not necessarily have to be in the storage section 305 get saved. In this case, even if the upper limit Nelm in the previous operation of the engine 200 was set, the derivative of the target discharge pressure PTr through the change process and determining if the upper limit Nelm is to be set, not performed as long as the time duration Tm of a state in which the difference described above Aps greater than or equal to the difference threshold ΔPSTh is not greater than or equal to the time duration threshold TMTH during the current operation of the engine 200 becomes. In contrast, the derivative of the target discharge pressure PTr through the change process and determining if the upper limit Nelm should be set, carried out when the period of time tm the state in which the difference Aps greater than or equal to the determination threshold ΔPSTh is greater than or equal to the time duration threshold TMTH becomes.

Because the oil pump 10 is a motor-driven pump, is the drive speed of the oil pump 10 proportional to the engine speed NE , The discharge pressure thresholds PSTh1 to PSTh3 can be increased discretely if the discharge pressure thresholds PSTh1 to PSTh3 can be set larger when the engine speed NE is relatively high, that is, when the input speed of the oil pump 10 is relatively high, as if the input speed is relatively low. For example, a threshold for the engine speed NE be set. In this modification, when the engine speed NE is less than the threshold, the discharge pressure thresholds PSTh1 to PSTh3 at values for engine speeds less than the threshold. When the engine speed NE is greater than or equal to the threshold, the discharge pressure thresholds become PSTh1 to PSTh3 maintained at engine speed values greater than the threshold. The engine speed values greater than the threshold are greater than the values for Engine speeds that are less than the threshold.

In the embodiment described above, a gear pump is used as the oil pump 10 used, however, the oil pump can 10 any type of pump other than a gear pump (eg a vane pump).

The oil pump may be an electric pump rather than a motor driven pump. Even in this case, it is possible to control the oil discharge pressure of the oil pump by adjusting the drive speed of the oil pump.

In the embodiment described above, the two discharge pressure thresholds become PSTh1 . pSTH2 as the upper limit setting thresholds, so that the upper limit Nelm for the engine speed NE can be adjusted in three stages. However, any number greater than or equal to three (e.g., four) of exhaust pressure thresholds may be provided as the upper limit adjustment thresholds, or only an upper limit adjustment threshold may be provided. Alternatively, instead of discretely setting the upper limit Nelm the upper limit Nelm are gradually increased when the Abdruckdrucksensorwert PS elevated.

In the embodiment described above, the target discharge pressure is PTr which is derived by the change process, equal to the maximum value of the oil discharge pressure that can be set at that time. However, the present disclosure is not limited thereto. In the modification process, the target discharge pressure PTr less than the maximum value of the oil discharge pressure that can be set at this time as long as the target discharge pressure PTr higher than the target discharge pressure PTr which is derived through the normal derivation process, ie, the reference purge pressure PTRB , For example, in the change process, the target discharge pressure PTr is set to a product obtained by multiplying the maximum value of the oil discharge pressure that can be set at that time by a value smaller than 1 (eg, 0.8). In addition, in the change process, the target discharge pressure PTr be adjusted to the sum obtained by supplying a predetermined offset value to the reference target discharge pressure PTRB is added.

The method of determining whether there is an abnormality in the control of the oil discharge pressure may be a method different from the method using the time duration Tm as described in the above-described embodiment. For example, in some cases, even if the engine increases 200 starts to work and the temperature of the coolant in the engine 200 circulates, increases, the oil temperature TMP Not. In such a case, it may be determined that there is an abnormality in the temperature sensor 312 and that there may be an abnormality in the control of the oil discharge pressure.

In the embodiment described above, when the discharge pressure sensor value becomes PS greater than or equal to the third discharge pressure threshold PSTh3 in a situation becomes, in which the oil drain pressure of the oil pump 10 with the nominal discharge pressure PTr Controlled by the change process is controlled, the control of the oil drain pressure based on the target discharge pressure PTr , which is derived by the change process, on the control of the oil drain pressure based on the target discharge pressure PTr , which is derived by the normal derivation process, changed. However, if the discharge pressure sensor value PS greater than or equal to the third discharge pressure threshold PSTh3 is the control of the oil drain pressure based on the target discharge pressure PTr , which is derived by the change process, continue even if the upper limit Nelm not for the engine speed NE is set.

The lower the oil temperature TMP is, the higher the viscosity of the oil. Accordingly, the oil drain pressure of the oil pump tends 10 to be relatively high. Thus, the third discharge pressure threshold PSTh3 be increased when the oil temperature TMP elevated. Additionally, the first discharge pressure threshold PSTh1 and the second discharge pressure threshold pSTH2 be increased when the oil temperature TMP elevated.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2012 [0003]
• JP 87729 A [0003]

Claims (8)

A control device for an onboard engine, wherein the onboard engine includes an oil pump capable of changing a discharge pressure and a sensor configured to detect a pressure of oil discharged from the oil pump, the control device comprising: a discharge pressure control section configured to control the oil discharge pressure of the oil pump based on a target discharge pressure that is a target value of a discharge pressure set for the oil pump and a discharge pressure sensor value that is a pressure of oil detected by the sensor ; an abnormality determination section configured to determine whether there is an abnormality in a control of the oil discharge pressure; a target changing section configured when the abnormality determination section determines that there is an abnormality in the control of the oil discharge pressure to execute a change process in which the target change section increases the target change pressure to a value greater than that before it is determined there may be an abnormality in the control of the oil discharge pressure; and an upper limit setting section configured such that when the discharge pressure sensor value in a situation in which the discharge pressure control section controls the oil discharge pressure based on the target discharge pressure increased by execution of the change process does not become equal to or greater than a discharge pressure threshold which is lower as the target purge pressure which is increased by the execution of the change process, the upper limit setting section sets an upper limit for an engine speed and increases the upper limit as the purge pressure sensor value increases. Control device for an onboard engine after Claim 1 wherein the abnormality determination section is configured to determine that there is an abnormality in the control of the oil discharge pressure when a time duration of a state in which a difference between the discharge pressure sensor value and the target discharge pressure is greater than or equal to a difference threshold value is equal to or greater than a time duration threshold value becomes. Control device for an onboard engine after Claim 1 or 2 wherein the target change portion is configured to equate the target purge pressure with a maximum target purge pressure, which is a maximum value of the target purge pressure that can be set for the oil pump, in the change process. Control device for an onboard engine according to one of Claims 1 to 3 wherein the oil pump is configured to be driven in synchronism with rotation of a crankshaft of the engine, and wherein the upper limit setting section is configured to set the exhaust pressure threshold larger when the engine speed is relatively high than when the engine speed is relatively low. Control device for an onboard engine according to one of Claims 1 to 4 wherein the upper limit setting section is configured to set the upper limit for the engine speed to set the upper limit larger when the Abdruckdrucksensorwert is greater than or equal to an upper limit setting threshold, which is less than the Abdruckdruckschwellenwert than when the Ablassdrucksensorwert is less than the upper limit Einstellschwellenwert. Control device for an onboard engine according to one of Claims 1 to 5 , further comprising a storage section storing a limit operation history which is an operation history indicating an operation of the onboard engine in a state where the upper limit for the engine speed is set, the target change section configured if the storage section sets the limit operation history at the start of the onboard engine stores to execute the changing process, whether or not the abnormality determination section has determined that there may be an abnormality in the control of the oil discharge pressure, and wherein the upper limit setting section is configured such that in a situation in which the discharge pressure control section sets the oil discharge pressure based on the target discharge pressure , which is increased by the execution of the change process, the upper limit setting section controls the upper limit in accordance with the Abdruckdrucksensorwert, when the Ablassdrucksensorwert is not greater than or equal to the discharge pressure threshold, and the upper limit setting section does not set the upper limit when the discharge pressure sensor value is greater than or equal to the discharge pressure threshold. Control device for an onboard engine according to one of Claims 1 to 6 wherein the target change portion is configured to terminate the execution of the change process when the discharge pressure sensor value is greater than or equal to the discharge pressure threshold value in a situation in which the discharge pressure control portion controls the oil discharge pressure based on the target discharge pressure increased by the execution of the change process. A control method for an onboard engine, wherein the onboard engine includes an oil pump capable of changing a discharge pressure and a sensor configured to detect a pressure of oil discharged from the oil pump, the control method comprising: Controlling the oil discharge pressure of the oil pump based on a target discharge pressure which is a target value of a discharge pressure set for the oil pump and a discharge pressure sensor value which is a pressure of oil detected by the sensor; Determining whether there is an abnormality in a control of the oil discharge pressure; when it is determined that there is an abnormality in the control of the oil discharge pressure, executing a change process to increase the target discharge pressure to a value greater than that before it is determined that there may be an abnormality in the control of the oil discharge pressure ; and when the discharge pressure sensor value in a situation in which the oil discharge pressure is controlled based on the target discharge pressure increased by execution of the change process does not become equal to or greater than a discharge pressure threshold lower than the target discharge pressure caused by the execution of the change process increasing, setting an upper limit for an engine speed and increasing the upper limit as the Ablassdrucksensorwert increases.

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